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DAFINET AND TARGETFISH FP7 WORKSHOP AND PH.D. COURSE
FISH MODELS IN RESEARCH
NOVEMBER 11TH
TO 13TH, 2014
Venue:
University of Copenhagen Frederiksberg Campus Lecture hall 2.01 (A1‐04.01) Grønnegaardsvej 7 1870 Frederiksberg C Denmark
Organised by:
DAFINET www.dafinet.dk
The Graduate School for Immunology and Infectious Diseases, KU‐SUND
TargetFish FP7
Book of abstracts
DAFINET and TargetFish FP7 Workshop, November 2014 University of Copenhagen
The workshop is supported by:
TargetFish which is a large collaborative project funded by the European Commission (Grant Agreement No. 311993) under the 7th Framework Programme for Research and Technological Development.
DAFINET, Danish Fish Immunology Network
P.C. Abildgaard Foundation
The Graduate School for Immunology and Infectious Diseases, Faculty of health and Medical Science, University of Copenhagen
The book of abstracts is edited by Per W. Kania and Kurt Buchmann
Illustrations by Kurt Buchmann, Copenhagen, Denmark
Printed by Frederiksberg Bogtrykkeri 2014 Frederiksberg, Denmark
DAFINET AND TARGETFISH FP7 WORKSHOP AND PH.D. COURSE
FISH MODELS IN RESEARCH Invited speakers: Peter Aleström Norway Jane Behrens Denmark Maria Forlenza, Netherlands Jorge Galindo‐Villegas Spain Simon Haarder Denmark Louise Jørgensen Denmark Scott LaPatra, USA Niels Lorenzen Denmark Barbara Nowak Australia Elke Ober Denmark Miguel Rubio‐Godoy Mexico Guiseppe Scapigliati Italy Sune Sørensen Denmark Jonna Tomkiewicz Denmark
NOVEMBER 11TH TO 13TH, 2014
Venue:
University of Copenhagen Frederiksberg Campus Lecture hall 2.01 (A1‐04.01) Grønnegaardsvej 7 1870 Frederiksberg C Denmark
Organised by:
DAFINET www.dafinet.dk
The Graduate School for Immunology and Infectious Diseases, KU‐SUND
TargetFish FP7
Welcome address and introductory remarks
K. Buchmann, University of Copenhagen, Denmark
The Danish Fish Immunology Research Center and Network (www.dafinet.dk) was
supported by the Danish Strategic Research Council from 2009 to 2013. Due to the exciting
results and stimulating discussions obtained during these five years we decided from 2014
to continue some of the activities now in collaboration with the graduate school of
infectious diseases and immunology at the Faculty of Health and Medical Sciences. We carry
on by organizing annual workshops in collaboration with TargetFish which is a large
collaborative project funded by the European Commission (Grant Agreement No. 311993)
under the 7th Framework Programme for Research and Technological Development. The
workshop is also supported by the Abildgaard Foundation established in the memory of Dr.
Peter Christian Abildgaard, the founder (in 1773) of the first veterinary school in Denmark
and Scandinavia. This excellent scientist was not only a brilliant fish parasitologist but was
also the first to carry out experimental infections when elucidating (in 1789) the life cycle of
the fish tapeworm Schistocephalus solidus. There is direct line from these early studies to
the workshop of today – elucidating how fish can be used as experimental models. Various
fish species are gaining increasingly higher importance worldwide, not only within
aquaculture production, but also within biological, molecular and biomedical research. The
use of fish as experimental animals and models has outnumbered the use of mammals such
as mice, rats and rabbits in certain countries such as Norway where far more than 1 mio fish
are being used for this purpose each year. Prominent classical species are Atlantic salmon,
rainbow trout and common carp but during the latest decades the zebrafish has obtained
status as the number one experimental fish of the future. However, due to the wide
variation within the fishes (which currently count around 30,000 species) with regard to
physiology, immunology and anatomy it will be important in the future to conduct
comparative studies within all scientific branches involving fish. It must be kept in mind that
although a certain fish species can be used as model for even human functions the genetic
distance between two fish species can be longer than that between carp and man. The
present workshop aims at addressing some of the research areas in which fish can be used
as models. By calling in excellent researchers covering more than nine fish species from
various taxonomic groups we hope to stimulate new contacts, collaborations and projects
taking these aspects into account.
Program
Tuesday November 11th, 2014
13:00 Professor Peter Alestrøm
Department of Basic Science Norwegian University of Life Sciences, Norway The maternal zygotic transition (MZT) in zebrafish
13:30 Associate Professor Elke Ober The Danish Stem Cell center, University of Copenhagen, Denmark Liver organogenesis in zebrafish
14:00 Ph.D. student Simon Haarder Laboratory of Aquatic Pathobiology, University of Copenhagen, Denmark Zebra fish as a model for inflammatory bowel disease (IBD): preliminary results
14:15 Coffee break
14:45 Research leader Dr. Scott LaPatra Clear Springs Foods Inc., Research Division, Buhl, Idaho, USA Biosecurity in fish keeping facilities
15:15 Postdoc Louise von Gersdorff Jørgensen Laboratory of Aquatic Pathobiology, University of Copenhagen, Denmark A search for new vaccine candidates in Ichthyophthirius multifiliis
15:30 Professor Niels Lorenzen Department of Animal Science ‐ Fish Health, Aarhus University, Denmark Rainbow trout as a model in functional studies of anti‐viral immunity
16:00 Professor Giuseppe Scapigliati Dept. DIBAF, University of Tuscia, 01100 Viterbo, Italy The European sea bass as a model species in immunobiology
16:30 Assistant Professor Maria Forlenza Animal Science Group, Wageningen University, The Netherlands
Common carp as experimental animal model
17:00 Final discussions and conclusions of the first DAFINET workshop day 18:00 Welcome Dinner
Program Wednesday November 12th, 2014
10:00 Professor Barbara Nowak NCMCRS AMC, University of Tasmania, Tasmania
Atlantic salmon as an experimental model
10:30 Research leader Dr. Scott LaPatra Clear Springs Foods Inc., Research Division, Buhl, Idaho, USA Methods Used for the Evaluation of Vaccine Efficacy
11:00 Research scientist Jane Behrens National Institute of Aquatic Resource, Technical University of Denmark
The parasitic copepod Lernaeocera branchialis negatively affects cardiorespiratory function in Atlantic cod (Gadus morhua)
11:30 Professor Barbara Nowak IMAS, University of Tasmania, Tasmania
Tuna as an experimental model
12:00 Lunch 13:00 Excursion to the Danish national Aquarium: The Blue Planet 16:00 Back to Frederiksberg Campus 18:00 Workshop dinner
Program Thursday November 13th, 2014
10:00 Professor Barbara Nowak NCMCRS AMC, University of Tasmania, Tasmania
Barramundi and other Australian fish species as experimental models
10:30 Postdoc Subhodeep Sarker Clinical Division of Fish Medicine, University of Veterinary Medicine, Austria
RNA interference (RNAi) as a possible control of whirling disease in rainbow trout (Oncorhynchuss mykiss)
10:50 Postdoc Jorge Galindo‐Villegas The Fish Phagocyte & Cytokine Lab, Faculty of Biology, Murcia University, Spain
Recent achievements on the evolution and diversity of the seabream immune system
11:10 Senior research scientist Jonna Tomkiewicz National Institute of Aquatic Resource, Technical University of Denmark
European eel as experimental model I: Assisted reproduction technology and standardized fertilization methods for mass production of viable embryos and larvae
11:40 Postdoc Sune Riis Sørensen Section for Population Ecology and Genetics, Technical University of Denmark
Improving biophysical rearing conditions during early life stages of European eel
12:00 Lunch 13:00 Professor Miguel Rubio‐Godoy Instituto de Investigaciones Biomédicas,
Universidad Nacional Autónoma de México Tilapia and poeciliid fishes as experimental models
13:30 Ph.D. student Hanne Haatveit Faculty of Veterinary Medicine and Biosciences, Norwegian University of Life Sciences, Norway The non‐structural proteins of piscine orthoreovirus, organizers of virus assembly?
13:50 Ph.D. student Jesper Kuhn Department of Arctic and Marine Biology, University of Tromsø, Norway
Effects of fish species composition on Diphyllobothrium spp. infections in subarctic brown trout and Arctic charr ‐ is the three‐spined stickleback a key species?
14:10 Ph.D. student Morten Lund Norwegian Veterinary Institute, Oslo, Norway Challenge models to clarify effects of piscine orthoreovirus (PRV) infection in blood cells on salmon robustness for oxygen deprivation, smoltification, stress and secondary infections
15:00 Final discussions and conclusions of the workshop
The maternal zygotic transition (MZT) in zebrafish P. Aleström
Department of Basic Science Norwegian University of Life Sciences, Norway
Zebrafish (Danio rerio), a tropical aquarium fish from the inland water systems of North‐East
India and Pakistan, was initially selected as vertebrate model for embryo development
because of its attributes of being a small, robust and easy to breed fish with transparent
embryos which develop to hatching within 48‐72 hours at 28°C. During the last 30 years a
detailed knowledge about zebrafish biology and genetics has been generated and is to a
large extent available to the international zebrafish community at the web site ZFIN. The
well‐organized access to zebrafish biology, genetics, husbandry and disease, as well as to
defined wild‐type strains, mutant and transgenic lines has resulted in a gradually growing
number of research areas taking zebrafish in use as model for human disease,
environmental toxicology, high‐throughput drug screening and more recently as model for
aquaculture relevant research.
The maternal zygotic transition (MZT) in zebrafish coincides with the mid‐blastula transition
(MBT) and the zygotic genome activation (ZGA) after 10 transcription‐independent cell
cycles at 3 hours post fertilisation (hpf), manifested by a gradual loss of pluripotency and the
on‐set of differentiation. With the development of new sequencing technologies,
transcriptomics and epigenomics it has been possible to uncover gene expression profiles,
epigenetic landscapes and noncoding (nc)RNAs and their contribution to early development
control. The transcriptome dynamics of over 8000 genes is characterized by different
patterns of maternal mRNA degradation and activation of dormant deadenylated
transcripts. Around 2000 cases of MZT isoform switches of transcripts expressed both
before and after ZGA suggest a complex picture of early differentiation control. ncRNAs
represent an increasing proportion of transcriptomes. The well described miR‐430 family
has an important role in maternal mRNA degradation control during the MZT. We are
currently characterizing pre MBT embryo stages for the presence of other functional short
ncRNAs. Methyl DNA immuno‐precipitation (MeDIP)‐chip and chromatin immuno‐
precipitation (ChIP)‐chip analyses around MZT stage embryos revealed that promoter DNA
methylation (5‐methyldeoxycytdine; 5mdC) dynamics, in relation to changes in post‐
translational histone modifications and gene expression profiles, suggests a pre‐patterning
of developmental genes consisting of a combination of DNA hypo‐methylation and H3K4m3
on CG‐rich promoters. During embryonic development the paternal genome is converted to
5‐hydroxymethyldeoxycytidine (5hmdC), as part of DNA methylation reprogramming and
5hmdC also perhaps serves as an epigenetic mark. Using high performance liquid
chromatography mass spectrometry to quantify global 5hmdC and 5mdC in zebrafish, low
levels of 5mdC (1.9%) were found at 0.5 hpf which increased to 8% up to 96 hpf. No 5hmdC
was detected before 12 hpf, but levels increased during development (0.23%). In summary
there seem to be a complex interplay between several epigenetic signals during the
preparation of the embryo for the MZT and the post MBT development.
Presenting author: Peter Aleström, [email protected]
Liver organogenesis in zebrafish
M. Poulain, D. Stamataki, J Cayuso and E. A. Ober
Danish Stem Cell Center, University of Copenhagen, Denmark
A fundamental question in biology is how organs are formed during development. Specifically,
how do organs with highly specialised cell types and distinct functions arise from a common pool
of multipotent progenitors. For example, in the vertebrate digestive system the nascent foregut
endoderm gives rise to the alimentary canal and its accessory organs, liver, pancreas, and the
respiratory lungs. Despite the many essential physiological functions of the digestive organs, our
knowledge of the mechanisms that control initial fate specification is limited. Still less understood
are the morphogenetic processes governing the precise position of the organs within the digestive
system, as well as their tissue architecture. Uncovering the principles underlying these processes is
important for regenerative medicine, as they are likely recapitulated at least in part during organ
regeneration and the differentiation of tissue‐specific stem cells and the creation of artificial
tissues. Our group combines zebrafish genetics with high resolution confocal imaging to
investigate the gene regulatory networks that specify liver cells from the foregut and subsequently
control their movements to assemble a liver bud and initiate organ outgrowth. We investigate the
signals that control the cell fate choice between liver and pancreas focussing on Wnt and Bmp
signals that originate from neighbouring tissues and are necessary for inducing hepatic fate. This
raises the question as to how these signals interact to specify liver. We show that loss of both
signals leads to a complete absence of liver, and conversely excess expression is sufficient to
convert pancreas progenitors to differentiate into liver. Using a candidate approach, we identified
a novel point of cross‐talk between both pathways. Notably, we found that a known Bmp‐inhibitor
seems to facilitate Wnt signaling and liver specification in this context. In a second project we
examine how the newly‐specified liver progenitors move to form an organ bud in the right place
and of the correct size. We identified two transmembrane proteins that control liver positioning in
the body by coordinating the movement of the liver progenitors with those of the neighbouring
tissues. Impaired gene function results in midline organs and malformed connecting ducts,
phenotypes reminiscent of congenital defects in humans. Ongoing work of developmental
regulators controlling liver progenitor specification and their subsequent movement mediating
liver bud assembly and outgrowth will be presented.
Presenting author: Elke A. Ober, [email protected]
Zebra fish as a model for inflammatory bowel disease (IBD): preliminary results
S. Haarder1, P.W. Kania1, P. Hyttel2, T.L. Holm3 and K. Buchmann1
1Laboratory of Aquatic Pathobiology, Department of Veterinary Disease Biology,
University of Copenhagen, Denmark
2Anatomy Group, Department of Veterinary Clinical and Animal Sciences, Faculty of Health and Medical Sciences, University of Copenhagen, Denmark
3Department of Immunopharmacology, Novo Nordisk A/S, Måløv, Denmark
Preliminary results from our inflammatory bowel disease (IBD) model in zebra fish (Danio
rerio) will be presented. Epidermal goblet cell depletion was seen in both oxazolone and
TNBS‐treated wild‐type adult fish and to a lesser degree in control fish. This result is
corresponding with findings in GI tracts of rodents with chemically‐induced colitis. Using
Optical Projection Tomography (OPT) we found an increased serotonin expression in
oxazolone‐treated intestines, suggesting a disturbance of signalling pathways. To further
characterize the model, real‐time polymerase chain reaction (qPCR) will be applied to study
the expression of a multitude of IBD‐relevant genes. Further, behaviour tracking of
challenged and control fish will hopefully allow us to describe the model from a non‐
invasive point of view.
Presenting author: Simon Haarder, [email protected]
Biosecurity in fish keeping facilities S. E. LaPatra
Clear Springs Foods, Inc., Research Division, Buhl, Idaho USA
“Biosecurity” means a lot of different things to a lot of different people. Biosecurity is
defined as implementing practices that minimize the risk of introducing an infectious
disease and spreading it to the animals at a facility and the risk that diseased animals or
infectious agents will leave a facility and spread to other sites and to other susceptible
species. Biosecurity practices also reduce stress to animals, thus making them less
susceptible to disease. Our policy emphasizes employee training, facility infrastructure, and
animal and pathogen management. Well trained employees function as the first line of
defense for any successful biosecurity program. There must be buy‐in by the employees for
any biosecurity program to be successful. Employees must be convinced on how this
program is going to benefit the company, the animal and their job. Essential to the
successful implementation of the biosecurity program are the adaptation of measures and
techniques that are simple, effective and convenient. Excluding access of possible vectors
onto farms is the next level of protection. Where possible, enclosures should be built over
incoming water sources and farms with the objective of preventing “contamination” of the
farm water supply and/or the farm itself. Good hygiene practices are essential for an
effective biosecurity program for the prevention of the introduction and spread of infectious
diseases. It is also important to understand and recognize the characteristics and signs of a
disease and the pathogens that cause various diseases so steps can be taken to contain and
solve the problem as soon as possible. The best way to prevent pathogen and disease
dissemination on a farm is to prevent epizootics from occurring. Vaccinology and selective
breeding should be emphasized along with passive fish handling and feed management.
Probably the single biggest challenge is attempting to understand the environment that the
fish are being cultured in. A better understanding of the culture environment and its
variability will allow optimization of all the different strategies being implemented and aid in
attaining the goal of your biosecurity program.
Presenting Author: Scott LaPatra, [email protected]
A search for new vaccine candidates in Ichthyophthirius multifiliis
L.vG. Jørgensen1, P.W. Kania1, K.J. Rasmussen2, A.H. Mattsson3 and K. Buchmann1
1Laboratory of Aquatic Pathobiology, University of Copenhagen, Denmark 2Department of Cancer and Inflammation Research, University of Southern Denmark
3CBS, Technical University of Denmark
Considerable vaccine research efforts have been conducted with regard to the
immobilization antigen Iag52b from the protozoan ciliate Ichthyophthirius multifiliis (Ich),
which infects most species of freshwater fish. Fish that survive an infection acquire a
subsequent level of immunity. The immunoglobulin IgM from immune rainbow trout and
channel catfish targets the immobilization antigen on the surface of the parasite and during
this process parasites become immobilized. Purified Iag52b injected together with Freund's
complete adjuvant may induce up to 72% protection in vaccinated fish following challenge –
however protection is only effective against one of the 5 parasite serotypes. Therefore, an
immunogenic antigen, which protects against all 5 serotypes and which can be easily
produced, is warranted. It has been shown that the mucosal immunoglobulin IgT from
immune rainbow trout also binds to the parasite. In this context there is no evidence that
lag52b represents an important antigen. Therefore, experiments were conducted to
elucidate which proteins IgT has affinity for. However, neither western blotting nor
immunoprecipitation provided a clear result. In order to identify new antigens we have now
turned to the use of the sequenced genome and the capabilities of neural networks. We
have used a program that can predict potential vaccine candidates from the genome alone
and select which ones may be suitable for production in a bacterial expression system. This
has not been without challenges and 5 of the selected 14 proteins contained so many
cysteines that we had to rethink the expression system. At the moment proteins are being
produced in E. coli and in a baculovirus expression system. Focus as aforementioned has
been on the antigen Iag52b and this protein came in as number 26 in the ranking of
potential vaccine candidates analyzing the whole proteome of strain G5 comprising 7200
proteins. We are at the moment testing the first 14 proteins on the ranking list.
Presenting author: Louise von Gersdorff Jørgensen, [email protected]
Rainbow trout as a model in functional studies of anti‐viral immunity
N. Lorenzen
Department of Animal Science, Aarhus University, Denmark
Salmonid rhabdoviruses like VHSV and IHNV are important pathogens in aquacultured
rainbow trout due to their high infectivity and virulence. At the experimental level, this is an
advantage in terms of the reproducible kinetics of infection trials following waterborne
exposure to virus multiplied in fish cell cultures. This has allowed detailed in vivo studies of
vaccine induced immunity as well as related protective mechanisms and concepts.
Vaccines based on plasmid DNA encoding the viral surface glycoprotein G under the control
can induce long‐lasting protective immunity when delivered by intramuscular injection in
rainbow trout fingerlings. Vaccination of fish at an early stage appears advantageous, since
larger fish require higher doses of vaccine to be protected. Even in fish with an average size
of 0.5 g at the time of vaccination, good protection can be obtained. Interestingly, immunity
is established already a few days after vaccination and cross‐challenge experiments have
revealed that protection in the early phase is non‐specific. Later on, protection becomes
very specific in terms of virus species. The protection in the early non‐specific phase is
related to interferon (IFN) induced defence mechanisms whereas specific antibodies and
cellular components both play a role in the long lasting protection. The similarity of the
functional immune response profile to that induced by a natural virus infection is striking
and is most likely one of the major reasons for the efficacy of the rhabdovirus DNA vaccines.
Although other elements like CpG motifs in the plasmid backbone sequence might play a
role, the viral G protein appears to have an inherent ability to stimulate innate immune
mechanisms by receptors and pathways that still remain to be characterized in detail.
Expression of the rhabdovirus G protein on the surface of transfected muscle cells induces a
histologically visible local inflammatory reaction with higher doses of VHSV G DNA vaccine.
Cell surface expression may be important for a proper activation of the fish immune system,
since blocking of the intracellular trafficking of the expressed glycoprotein G‐gene interfere
with protection. It was recently discovered that upregulation of certain micro RNAs is
among the early innate response elements induced by VHSV infection as well as by DNA
vaccination. Micro RNAs (miRs) interfere with protein expression at the posttranslational
stage by specific binding to the 3´UTR part of mRNAs. By injection of so called anti‐miRs
after innate immune stimulation followed by challenge with VHSV, it was possible to
demonstrate that the highly upregulated miRs contribute to IFN induced protection. In the
adaptive phase of protection, neutralizing antibodies are involved in protective immunity to
VHSV in rainbow trout. Trout antibodies appear to neutralize the virus in a complement
dependent manner, whereas mammalian IgG antibodies can neutralize the virus by
themselves. Even small recombinant single chain antibody molecules can neutralize the
virus in vivo. This was demonstrated in a gene‐based delivery approach, which might have
perspectives in human immunotherapy. Viral disease models in rainbow trout can thus be
useful for conceptual studies both within and beyond the veterinary level.
Presenting author: Niels Lorenzen, [email protected]
The European sea bass as a model species in immunobiology G. Scapigliati
Dept. DIBAF, University of Tuscia, 01100 Viterbo, Italy
The European sea bass (Dicentrarchus labrax), with a production of 150 kT (2012, from
FAO), is the main non‐salmonid marine species farmed in Europe. Due to its importance, the
sea bass is a subject of intense research to investigate its physiology for evolutionary and
applicative purposes. Of particular importance is the research on sea bass immunobiology,
in order to protect the fish against microbial infections in farming conditions, and much
information is now available on cellular and molecular immune defences, due to the
availability of cellular and molecular markers. Regarding cell biology of leukocytes, there is a
marked difference in the content of T cells and B cells among tissues, with T cells being
preponderant in mucosal tissues and IgM‐B cells in non mucosal tissues. The number of T
cells is particularly high in the intestine, and can be modulated by changing the intestinal
microbiome. The T cells are able to proliferate in vitro in response to either allo/xeno
recognition and to lectins (conA, PHA), showing a tissue‐dependent response. The B cells
show antigen‐specific serum IgM antibody responses, the presence of memory B cells can
be elicited by systemic (intraperitoneal) administration of antigens, whereas mucosal
administration of antigens (immersion) does not induce specific serum IgM antibody.
The deep‐sequencing of transcriptomes from unstimulated thymus and gills provided useful
information on expressed immune gene transcripts. The gills display an entire set of
expressed genes coding for T cell populations (CD3, CD4, CD8) and subpopulations (Th1,
Th2, Th17, Treg), as well as master regulators of T cell responses as they are known in
mammals, and B cell populations (IgM, IgD, IgT). The intestine is a site of T cell expression
and lymphocyte differentiation, where RAG‐driven somatic recombination occurs in
response to antigen administration. Attention is now focused on antiviral responses of sea
bass against a main pathogen, the betanodavirus (VERv), and preliminary results show
measurable variation in the transcription of antiviral genes in the gills in response to
mucosal (immersion) vaccination. Overall, after two decades of studies, the sea bass is
considered a marine fish model to investigate the immunobiology of fish and vertebrates.
Research funded by the EU (6FP IMAQUANIM, 7FP TARGETFISH).
Presenting author: Giuseppe Scapigliati, [email protected]
Common carp as experimental animal model
M. Forlenza
Animal Science Group, Wageningen University, The Netherland
The common carp (Cyprinus carpio) is a freshwater fish and is one of the most cultured fish
species in the world. Especially in China, common carp accounts for 2.5 million metric
tons/year. It is not a high value fish but it’s beautiful cousin, the koi carp, can reach values of
150.000 Euro per fish, making koi the most expensive fish in the world. In this presentation I
will show you how studies on carp have helped to elucidate fundamental aspects of the fish
immune system. Using various infectious pathogens and owing to the availability of several
leukocyte‐specific antibodies, we have gained insights into humoral and cellular responses
of carp to pathogens. In our group, we have recently gained access to the sequenced carp
genome, and thanks to the close phylogenetic distance of carp to zebrafish (Danio rerio) we
can easily identify and annotate large numbers of immune genes. Finally, I will conclude by
giving some examples on how we have been able to use our current knowledge for the
development of experimental vaccines against carp viruses and how the combined use of
carp and zebrafish animal models should be considered a perfect ‘twinning’ match for
future research in fish.
Presenting author: Maria Forlenza, [email protected]
Atlantic salmon as an experimental model B. Nowak
IMAS University of Tasmania, Australia
Atlantic salmon is a species closely related to rainbow trout which has been used as a model
species for a long time resulting in well‐developed research tools, some of them applicable
to Atlantic salmon. Atlantic salmon has significantly higher commercial significance than
rainbow trout. While it is native to the area of Northern Atlantic Ocean, this species is
farmed on all continents with the exception of Asia and Antarctica. Atlantic salmon is the
main fish species farmed in Australia. With its genome publicly released in June 2014 by the
International Cooperation to Sequence the Atlantic Salmon Genome, Atlantic salmon is now
even more attractive as a model species. This presentation will discuss the use of Atlantic
salmon as a model species. Disease models developed for Atlantic salmon to study fish
immune response, including yersiniosis and Amoebic Gill Disease and in vitro models using
Atlantic salmon organs and cells will be also presented.
Presenting author: Barbara Nowak, [email protected]
Methods Used for the Evaluation of Vaccine Efficacy S. E. LaPatra
Clear Springs Foods, Inc., Research Division, Buhl, Idaho USA
In order to evaluate vaccine efficacy accurately, functional measures such as adaptive,
innate and/or mucosal immunity need to be evaluated along with the kinetics of protection
and relative percent survival (RPS) using a robust and reproducible pathogen challenge
system. The experimental design for the challenge should include replicates of each
treatment group and mortality >60% in the mock vaccinated controls at the completion of
the challenge. During the challenge the pathogen should be re‐isolated from a portion of
the mortality and quantitated to confirm the cause of death. Measures of vaccine efficacy
that can be statistically analyzed include cumulative percent mortality (CPM), mean number
of days to death (MDD) and RPS. The challenge methods that are commonly used include
injection, immersion, co‐habitation and oral delivery of the pathogen and each one has
advantages and disadvantages. The co‐habitation challenge system is probably the most
“real life” but takes the most effort to develop a consistent and reproducible methodology.
Serological methods for the evaluation of vaccine efficacy require determining the
functionality of antibody or other serum component(s) that can be consistently and
accurately measured. The “process” in determining the functionality of a serum component
includes evaluating the susceptibility of survivors to re‐infection using a controlled pathogen
challenge system. If the survivors are resistant to re‐infection then various serum
components can be investigated and a measurement method developed. The functionality
of this component can be verified using passive transfer and challenge studies. Once verified
this factor could be used as an indicator of vaccine efficacy. Vaccine efficacy can also be
assessed by evaluating the kinetics of protection using onset and specificity studies that call
for challenging fish from different treatment groups at 100 and 400 degree days and also
evaluating long duration protection. There is a need for the development of a standardized
procedure for the evaluation of vaccine efficacy.
Presenting Author: Scott LaPatra, [email protected]
The parasitic copepod Lernaeocera branchialis negatively affects cardiorespiratory function in Atlantic cod (Gadus morhua)
J.W. Behrens1, H. Seth2, M. Axelsson2 and K. Buchmann3
1 National Institute of Aquatic Resources, Technical University of Denmark, Denmark
2 Department of Biological and Environmental Sciences, University of Gothenburg, Sweden
3 Laboratory of Aquatic Pathobiology, University of Copenhagen, Denmark
The female of the parasitic copepod Lernaeocera branchialis L. parasitizes the gills of
Atlantic cod Gadus morhua and other closely related gadoids. Furthermore, the head and
appendages penetrate into the ventral aorta and bulbus arteriosus of their host. The
parasite’s pathogenic properties primarily include penetration of the gill epithelia as well as
feeding on blood and occlusion of blood vessels (Kabata 1979. Parasitic copepod of British
fishes. Ray Society, London, UK). We here show that despite the potential for adaptive
anatomical modifications to maintain cardiac output (Gamperl & Farrell, 2004. Cardiac
plasticity in fishes: environmental influences and intraspecific differences. J. Exp. Biol. 207:
2539‐2550), G. morhua cardiorespiratory performance is severely affected following
consecutive L. branchialis infections. This has the potential to negatively impact the
postprandial metabolic response, reflecting the capacity for anabolic and catabolic
processes in the post‐absorptive state of fish.
Presenting author: Jane Beherens, [email protected]
Tuna as an experimental model B. Nowak
IMAS University of Tasmania, Australia
Bluefin tunas (Atlantic Bluefin Tuna ‐ ABT, Pacific Bluefin Tuna ‐ PBT and Southern Bluefin
Tuna ‐ SBT) are highly evolved fish species, characterised by their large size, wide range,
efficient swimming, thermoregulation and other physiological adaptations making them
best adapted to life in open oceans and extensive oceanic migrations that they undertake
during their lives.
These species have very high market value and some of them have been declared
endangered or threatened. All of these species are ranched (cage grow‐out of wild
juveniles for a limited time) but only PBT life cycle was closed in 2002 by Kinki University
Japan and this species is now produced by hatcheries for cage grow out. While it is not
logistically possible to run in vivo experiments with SBT, this species is very useful for in vitro
studies. This presentation will review research on SBT and PBT and their potential use as
model species for a range of research areas, including aquatic toxicology.
Presenting author: Barbara Nowak, [email protected]
Barramundi and other Australian fish species as experimental models
B. Nowak
IMAS University of Tasmania, Australia
Barramundi, Lates calcarifer, is a fish species which is commercially important in a number
of Asian countries and Australia. Barramundi grows very fast in a range of environmental
conditions and has been also farmed in Europe and North America. This species is easy to
maintain under laboratory conditions and it is amenable to experimental manipulation. Its
compact genome (approximately 700 Mb) is one of the smallest genomes of farmed fish
species. All this makes barramundi an interesting model species. Other species discussed in
this presentation include sand flathead, Platycephalus bassensis, yellowtail kingfish, Seriola
lalandi, and striped trumpeter, Latris lineata. In particular, the potential of these species to
be used as models, in particular in aquatic toxicology and aquatic pathology, will be
discussed.
Presenting author: Barbara Nowak, [email protected]
RNA interference (RNAi) as a possible control of whirling disease in rainbow trout (Oncorhynchuss mykiss)
S. Sarker and M. El‐Matbouli
University of Veterinary Medicine, Vienna, Austria
Whirling disease caused by the myxosporean agent, Myxobolus cerebralis, is a problem in
the European Aquaculture industry and poses a threat to the survival of wild rainbow trout
(Oncorhynchus mykiss) in North America (El‐Matbouli et al. 1999; Hedrick & El‐Matbouli
2002; Hedrick et al 2003). The life cycle of M. cerebralis alternates between two
transmission stages: an actinosporean triactinomyxon spore that develops in an aquatic
oligochaete, Tubifex tubifex and M. cerebralis myxospores that develop in salmonid host (El‐
Matbouli et al. 1999). An experimental approach to control whirling disease by breaking
down the life cycle of M. cerebralis in oligochaete host using RNA interference (RNAi)
technology will be described. Specifically, how small interfering RNAs (siRNAs) will target
important genes of M. cerebralis to: (i) hinder the development of the triactinomyxon
actinospores in the oligochaete host or, (ii) to down regulate the expression of genes
important for spore’s pathogenesis in the oligochaete host to prevent it from infection of
rainbow trout and subsequent development of whirling disease.
Presenting author: Subhodeep Sarker, [email protected]
Seabream as a model to elucidate evolution and diversity of the immune system
J. Galindo‐Villegas and V. Mulero
The Fish Phagocyte & Cytokine Lab, Faculty of Biology, Murcia University, Spain
Fish represent the oldest and most diverse classes of vertebrates, comprising around the
48% of the known member species in the subphylum Vertebrata. The Teleost Gilthead
seabream (Sparus aurata), which belongs to the wide spread order Perciformes, is a major
farming species under intensive culture level in open waters of many Mediterranean
countries. This condition turns it as a clear target for diverse opportunistic pathogens
causing infectious diseases. However, until recently, the seabream immune defence
mechanisms, and the ontogeny of their innate immune cells has been poorly understood. In
this presentation I will comment on how we succeed, using this immunologically tractable
fish model, to establish the correct timing in which innate and adaptive genes develop and
achieve immunocompetence against specific antigens. To effectively discriminate among
the diverse cell types involved in fish phagocytic defence, we produced and characterized
specific antibodies (G7 and Mcsfr) against the two major professional phagocyte
populations present in this species, namely acidophilic granulocytes (functionally equivalent
of mammalian neutrophils) and monocytes/macrophages respectively. Furthermore, we
gain insight into the phylogeny of the acidophilic granulocytes, and achieve to describe an
outstanding evolutive process, the presence of biologically active histamine in mast cells
which are recognized as important initiators and effectors of innate immunity. Thereafter,
we explored for the presence and the spatial distribution of signaling pattern recognition
receptors in leukocytes. Findings indicate that receptors are diversely located and display
highly mammalian homology, despite the fish gene duplication phenomena. Additionally,
using seabream macrophages we found “ex‐vivo” a caspases‐1 independent processing and
release of the inflammatory marker IL‐1β, and surprisingly, got to identify even a new
member of the IL‐1 family (IL‐1Fm2). Thus, now our efforts are focused in developing a
targeted mucosal vaccination strategy applying the immune knowledge in addition to strong
adjuvants and designed toxoid preparations in order to increase seabream disease
resistance against the widely spread disease pasteurellosis.
Presenting author: Jorge Galindo‐Villegas, jorge‐[email protected]
European eel as experimental model I: Assisted reproduction technology and standardized fertilization methods for mass production of viable embryos and larvae
J. Tomkiewicz
DTU Aqua, Fish Biology Group, Technical University of Denmark, Denmark
Eels (Anguilla spp.) belong to the elopomorph superorder, a group of phylogenetically
ancient teleosts that possesses very unusual features in their multi‐stage catadromous life
cycle as well as in their different ontogenetic stages. The one characteristic uniting this
group of fishes is that they all have leptocephalus larvae, which are unique to the
Elopomorpha. Furthermore, key aspects of their life cycle still rank among the great
unsolved mysteries of biology, the most obvious being that there is still no direct
observational evidence on the oceanic migrations of anguillid silver eels to their spawning
areas and spawning itself. Even today, spawning sites are exclusively recognized by
delimiting the occurrence of leptocephalus larvae on their journey towards growth areas in
continental waters.
Prior to spawning migration, juvenile yellow eels enter the silvering process, where
morphological and physiological changes take place; however, the migratory silver eels are
still sexually immature. Sexual maturation and gonadal development in eels, as in other
vertebrates, is regulated by gonadotropic follicle‐stimulating hormone (FSH) and luteinizing
hormone (LH) that are produced by the pituitary. However, in the silver eel stage, sexual
development is suppressed by a dopaminergic inhibition at the brain‐pituitary level. This is
likely an adaptation related to their long migration to the spawning site, especially in
temperate species, where e.g. the European eel (A. anguilla) migrate ~6000 km from the
European continent to the Sargasso Sea. If prevented from undertaking their oceanic
migration, sexual maturation and gonad development remains blocked by this dopaminergic
inhibition of pituitary activity and absence of stimulation by Gonadotropin‐Releasing
Hormone. This inhibition must be released once the eels approach the spawning site,
however the mechanism behind this physiological regulation remains unresolved.
The complex hormonal regulation of eel sexual maturation and gonadal development has
motivated the choice of eel as an experimental model for studies on the development and
physiological functions of the reproductive endocrine system. The knowledge generated
through this research has given rise to methodologies applied in captive reproduction of
eels, using salmon or carp pituitary extracts as sources of FSH and LH for induction of
vitellogenesis in female eel and hCG for induction of spermatogenesis in male eel. In female
eel, oocyte maturation that precedes ovulation is regulated by LH and the maturation‐
inducing steroid, 17α, 20β‐dihydroxy‐4‐pregnen‐3‐one, DHP). Also this intricate process is
induced hormonally by administration of e.g. DHP.
Challenges in European eel reproduction experiments include optimizing the efficacy of
hormonal treatments, and thereby gamete production, quality and offspring developmental
competence. In recent years, improvements in assisted reproduction technology including
standardized fertilization methods has promoted mass production of viable eggs and larvae,
which now allows experimental work on larval culture technology. Successful captive
breeding and establishment of hatchery technology for commercial production of glass eels
is fundamental to future sustainable aquaculture for this endangered species, and would
allow the industry to rebuild the highly profitable market for eel aquaculture and suppliers.
Presenting author: Jonna Tomkiewicz, [email protected]
Improving biophysical rearing conditions during early life stages of European eel
S.R. Sørensen
Section for Population Ecology and Genetics, Technical University of Denmark, Denmark
Although the European eel are reared in aquaculture, this industry relies solely upon wild‐
caught juvenile glass eels that arrive to the European coasts after a 6000 km journey from
the Sargasso Sea, where they were hatched. Within the European continent, eels are in an
immature stage and although, attempted since 1930, utilizing maturational hormones, we
only recently succeeded in refining reproduction protocols enabling rich quantities of viable
gametes to support captive reproduction. In view of these obstacles, the last decade’s
research has shown substantial progress which builds on large effort to develop
standardised protocols for fertilization which was not present. Milt and egg characteristics
hold early clues on viability and we aimed at improving knowledge on characterizing
gametes produced through induced maturation. We identified standardized sperm
quantification tools and best ratios for mixing of sperm and egg prior to the activation of
both gametes in the marine environment. Improper activation and swelling of in vitro
produced eggs was frequently observed however and seen to negatively affect embryonic
development and hatching. Consequently we aimed to establish improved biophysical
conditions for the fertilization and incubation both establishing standardized experimental
conditions and improving survival. We found activation salinities and salt types to influence
both egg quality and egg diameters to species specific dimensions. Yet another aim was to
lower high mortalities in late embryonic and early larval stages. Here we found microbial
conditions being of pivotal importance by suppressing microbial coverage on eggs and
microbial activity on both eggs, and larval and seeing a remarkably improvement in hatch
and larval longevity which can be significantly improved. These important steps in the early
life stages of European eel have been significantly improved through our work within the
recent decade and render this species a potential new species being fully and sustainably
produced in aquaculture.
Presenting author: Sune Riis Sørensen, [email protected]
Tilapia and poeciliid fishes as experimental models M. Rubio‐Godoy
Instituto de Ecología, A.C., Mexico
Tilapia (Oreochromis spp.) are African fish nowadays cultured worldwide. Poeciliid fishes
(“guppies”) are originally South American but have also been translocated globally with the
aquarium trade. Both are interesting models for basic and applied parasitological research.
In this talk, I will present examples of the sort of experimental data obtained with these
fishes in Mexico – and elaborate on their implications. For instance, in farmed tilapia, the
distribution and abundance of the monogenean Gyrodactylus cichlidarum seem to be
regulated by host immunity. The study of gyrodactylids infecting poeciliid fishes in Mexico
not only contributes to the inventory of a recognized biodiversity hotspot, but also provides
clues to the phylogeographical co‐evolution of hosts and parasites. Finally, digenean
parasites (Phyllodistomum spp.) of Mexican poeciliids will be shown as a case study to
advocate for the use of an integrative taxonomical approach; i.e., one that combines as
many sources of information as possible to describe new species (morphological, molecular,
microscopic, ecological, etc.).
Presenting author: Miguel Rubio‐Godoy: [email protected]
The non‐structural proteins of piscine orthoreovirus, organizers of virus assembly?
H.M. Haatveit, I.B. Nyman, Ø.W. Finstad, M.K. Dahle and E. Rimstad
Faculty of Veterinary Medicine and Biosciences, Norwegian University of Life Sciences, Norway
Piscine orthoreovirus (PRV) is associated with heart‐ and skeletal muscle inflammation
(HSMI) in farmed Atlantic salmon. Phylogenetic analysis of PRV has revealed a taxonomic
placement within the family Reoviridae, most closely related to the genus Orthoreovirus.
Reoviruses are spherical non‐enveloped viruses with icosahedral capsids surrounding the
double stranded RNA (dsRNA) genome. The PRV genome consists of 10 dsRNA segments
distributed in the classical orthoreoviral groups of three large, three medium and four small
segments. Mammalian orthoreovirus (MRV) has been studied extensively and is currently
used as basis for constructing a model for PRV replication. The PRV segments M3 and S3
encode the non‐structural (NS) proteins μNS and σNS. The NS proteins are believed to be
involved in establishment of viral factories. Viral factories are intracellular compartments
(inclusions) where replication, packaging and assembly of novel viral particles occur.
In this study, we have cloned the PRV NS proteins and tagged them in the N‐ and C‐terminus
for recognition by available antibodies. The tagged proteins were expressed in fish cell lines,
and the subcellular localization and co‐localization between the two NS proteins was
studied by confocal microscopy. We also studied the ability of μNS to assemble and co‐
localize with two of the structural PRV proteins, λ1and μ2. Our results demonstrated that
μNS forms dense globular inclusions much similar to viral factories when expressed in fish
cells. μNS assembles and co‐localize with σNS as well as the structural proteins λ1 and μ2.
Future studies will include an attempt to characterize motifs necessary for inclusion
formation in the μNS protein.
Presenting author: Hanne Haatveit, [email protected]
Effects of fish species composition on Diphyllobothrium spp. infections in subarctic brown trout and Arctic charr ‐ is the three‐spined stickleback a key species?
Kuhn, J. A., Knudsen, R., Kristoffersen, R., Amundsen, P.‐A.
Department of Arctic and Marine Biology, University of Tromsø, Norway
Subarctic brown trout (Salmo trutta) populations are often heavily infected with
plerocercoid larvae of the cestode genus Diphyllobothrium, assumedly as a consequence of
piscivorous behavior. Three‐spined sticklebacks (Gasterosteus aculeatus) are frequently
preyed upon by trout and are commonly infected with D. ditremum and D. dendriticum.
These parasites may transmit from fish prey to fish predators, and predation on sticklebacks
may therefore be the main reason for the elevated parasite infections observed in
piscivorous salmonids. As sticklebacks are easily caught prey, their presence might also
enhance the abundance of piscivorous birds functioning as final hosts for the parasites. This
would increase parasite transmissions and result in an overall higher parasite load in the
lake. To explore possible effects of fish species composition and in particular the presence of
sticklebacks on the diphyllobothrid infections of lacustrine salmonids, we contrasted data
from eight brown trout populations representing four different fish species compositions
(trout in allopatry, trout in sympatry with Arctic charr (Salvelinus alpinus), trout in sympatry
with stickleback, and trout in sympatry with charr and stickleback). Our findings suggest that
sticklebacks do in fact play an important role for the diphyllobothrid infections in lacustrine
salmonid populations.
Presenting author: Jesper Kuhn, [email protected]
Challenge models to clarify effects of piscine orthoreovirus (PRV) infection in blood cells on salmon robustness for oxygen
deprivation, smoltification, stress and secondary infections M. Lund1, O.W. Finstad2, V. Aspehaug3, S.M. Jørgensen4, E. Rimstad2 and M.K. Dahle1
1Norwegian Veterinary Institute, Oslo, Norway
2NMBU, Oslo, Norway
3Patogen AS, Ålesund, Norway
4NOFIMA, Ås, Norway
In the 1990s, heart and skeletal muscle inflammation (HSMI) were first reported in Atlantic
salmon in Norway, and later in Scotland (Kongtorp RT. 2004, HSMI in Atlantic salmon.
Ferguson HW. 2005). HSMI is characterized by epicarditis, myocarditis and myocitis in red
skeletal muscle (Kongtorp RT, 2004. HSMI in Atlantic salmon). Piscine orthoreovirus (PRV)
was found to be associated with the disease in 2010 by Palacios et al (PLoS One). Studies on
PRV pathogenesis in Atlantic salmon performed by Finstad, Dahle, Rimstad and co‐workers
at NMBU and NVI demonstrated in 2013 that PRV massively infects red blood cells (RBC)
prior to infection of the heart in HSMI. Links between PRV‐infection and secondary
infections, stress sensitivity and reduced smolt quality has been suspected from screening
studies in aquaculture but not systematically tested. These connections could be partly be
explained by the massive infection of RBC.
The collaborators of this current research project, HSMI‐more, shall execute three
controlled cohabitation challenge studies. The first challenge study aims to elucidate the
effect of PRV infection on smoltification in Atlantic salmon. The second study will clarify the
effect of PRV infection in RBC on sensitivity to oxygen deprivation and stress. The final
challenge study will look at the interaction between PRV and salmonid alphavirus (SAV), the
virus responsible for pancreas disease (PD), in a co‐infection challenge model.
Presenting author: Morten Lund, [email protected]
List of participants
First name Surname e‐mail Affiliation
Leonardo Mantilla Aldana [email protected]
Edificio de Ciencias experimentales, Campus As Lagoas‐Marcosende, Spain
Peter Aleström [email protected]
Department of Basic Science and Aquatic Medicine, Norwegian University of Life Sciences, Norway
Azmi Al‐Jubury [email protected] Department of Veterinary Disease Biology,University of Copenhagen, Denmark
Manfrin Amedeo [email protected] Fish Pathology Unit, Istituto Zooprofilattico Sper.le delle Venezie, Italy
Liu Anjian Branch Company Maoming, Tongwei Co., LTD., China
Qusay Bahlool [email protected] Department of Veterinary Disease Biology,University of Copenhagen, Denmark
Simona Bartkova [email protected] National Veterinary Institute, Technical University of Denmark
Jane Behrens [email protected] National Institute of Aquatic Resource, Technical University of Denmark
Morten Sichlau Bruun [email protected] National Veterinary Institute, Technical University of Denmark
Kurt Buchmann [email protected] Department of Veterinary Disease Biology,University of Copenhagen, Denmark
Chiara Bulfon [email protected] University of Udine, Department of Animal Science, Italy,
Erika Burioli [email protected] Fish Pathology Lab, Istituto Zooprofilattico Sperimentale del Piemonte, Italiy
Ejner Børsting [email protected] Bjæverskov, Denmark
Jiwan Kumar Chettri [email protected] Department of Veterinary Disease Biology,University of Copenhagen, Denmark
Inger Dalsgaard [email protected] National Veterinary Institute, Technical University of Denmark
Xiao Dan Animal Health Institute, Tongwei Co., LTD., China
Maria Forlenza [email protected] Animal Science Group, Wageningen University, The Netherlands
Camilla Frandsen [email protected] Department of Veterinary Disease Biology,University of Copenhagen, Denmark
Jorge Galindo‐Villegas jorge‐[email protected]
Department of Cell Biology and Histology, University of Murcia, Spain
Christina Hejl Holm‐Hansen [email protected] Department of Veterinary Disease Biology,University of Copenhagen, Denmark
Simon Haarder [email protected] Department of Veterinary Disease Biology,University of Copenhagen, Denmark
Hanne Haatveit [email protected] NMBU veterinærhøgskolen
Dimitra Iakovaki [email protected] Department of Veterinary Disease Biology,University of Copenhagen, Denmark
List of participants
First name Surname e‐mail Affiliation
Louise von Gersdorff Jørgensen [email protected]
Department of Veterinary Disease Biology,University of Copenhagen, Denmark
Per Kania [email protected] Department of Veterinary Disease Biology,University of Copenhagen, Denmark
John Peter Hewa Kinyage [email protected]
National Food Institute, Technical University of Denmark, Denmark
Jesper Andreas Kuhn [email protected] Department of Arctic and Marine Biology, University of Tromsø Norway
Rozalia Korbut [email protected] Department of Veterinary Disease Biology,University of Copenhagen, Denmark
Scott LaPattra [email protected] Clear Springs Foods, Inc., Idaho, USA
Jens Lauritz Larsen [email protected] Department of Veterinary Disease Biology,University of Copenhagen, Denmark
Anne Hjørngaard Lauritzen [email protected] Biomar, Denmark
Thomas Lidenstrøm [email protected] Statens Seruminstitut, Denmark
Niels Lorenzen [email protected] Department of Animal Science ‐ Fish Health, Aarhus University, Denmark
Morten Lund [email protected] Section of Immunology, Norwegian Veterinary Institute, Norway
Lone Madsen [email protected] National Veterinary Institute, Technical University of Denmark
Moonika Haahr Marana [email protected] Department of Veterinary Disease Biology,University of Copenhagen, Denmark
Sanaz Mazaheri [email protected] Department of Veterinary Disease Biology,University of Copenhagen, Denmark
Foojan Mehrdana [email protected] Department of Veterinary Disease Biology,University of Copenhagen, Denmark
Rzgar Jaarfar Mohammad [email protected] Department of Veterinary Disease Biology,University of Copenhagen, Denmark
Ole Sten Møller [email protected] Zoological Museum,
Kristian Ege Nielsen [email protected] Department of Veterinary Disease Biology,University of Copenhagen, Denmark
Barbara Nowak [email protected] IMAS, University of Tasmania, Tasmania
Elke Ober [email protected] Danish Stem Cell Center, University of Copenhagen, Denmark
Niels Jørgen Olesen [email protected] National Veterinary Institute, Technical University of Denmark
Maki Otani [email protected] Department of Veterinary Disease Biology,University of Copenhagen, Denmark
Egle Petkeviciute [email protected] Department of Veterinary Disease Biology,University of Copenhagen, Denmark
Marie Plambech [email protected] National Institute of Aquatic Resource, Technical University of Denmark
List of participants
First name Surname e‐mail Affiliation
Sebastian Nikitas Politis [email protected]
National Institute of Aquatic Resources, Technical University of Denmark
Miguel Rubio‐Godoy [email protected] Instituto de Investigaciones Biomédicas, Universidad Nacional Autónoma de México
Kasper Rømer Villumsen [email protected]
Department of Veterinary Disease Biology,University of Copenhagen, Denmark
Subhodeep Sarker [email protected] Clinical Division of Fish Medicine, University of Veterinary Medicine, Austria
Giuseppe Scapigliati [email protected] Department of Environmental Sciences University Of Tuscia, Italy
Jacob Günther Schmidt [email protected] National Institute of Aquatic Resources, Technical University of Denmark
Priscilla Seah [email protected] Department of Veterinary Disease Biology,University of Copenhagen, Denmark
Jakob Skov [email protected] Department of Veterinary Disease Biology,University of Copenhagen, Denmark
Alf Skovgaard [email protected] Department of Veterinary Disease Biology,University of Copenhagen, Denmark
Jonas Steenholdt Sørensen [email protected]
Department of Veterinary Disease Biology,University of Copenhagen, Denmark
Sune Riis Sørensen [email protected] Section for Population Ecology and Genetics, Technical University of Denmark
Helena Elisabeth Hou Thomassen [email protected]]
National Veterinary Institute, Technical University of Denmark
Helena Elisabeth Hou Thomassen [email protected]
National Food Institute, Technical University ofDenmark, Denmark
Liu Tianqiang Animal Health Institute, Tongwei Co., LTD., China
Jonna Tomkiewicz [email protected] National Institute of Aquatic Resource, Technical University of Denmark
Niccolò Vendramin [email protected] National Veterinary Institute, Technical University of Denmark
Donatella Volpatti [email protected] University of Udine, Department of Animal Science, Italy,
Albert Willemsen [email protected] Noldus Information Technology bv, The Netherlands
Cheng Xiaoru Special Feed Research Institute, Tongwei CO., LTD., China
Guo Yizhong Tongwei CO., LTD., China
Cheng Yuanfang Livestock and Poultry Research Institute, Tongwei CO., LTD., China
Lara Zheng EU Project Innovation Centre
Bent Aasted [email protected] Department of Veterinary Disease Biology,University of Copenhagen, Denmark